Plasma stratification in radio-frequency discharges in argon gas

Kolobov, Vladimir; Arslanbekov, Robert; Levko, Dmitry; Godyak, Valery

doi:10.1088/1361-6463/ab7ca0

Cited by 31 publications

(41 citation statements)

References 17 publications

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“…The development of instability in the radial direction causes the discharge contracting into a thin cord (constriction) to eliminate the stabilizing factor and leads to a nonlinear dependence of the ionization rate on plasma density in the longitudinal direction (striation). [7,16,28]…”

Section: Ev) + Ar (1s )mentioning

confidence: 99%

“…The nonlinear dependence of the ionization rate on the plasma density is the common underlying mechanism in DC striations of noble gases. [6,7] Though AC RF striations have been found to be generated due to the ionresonance between the driving RF and the eigenfrequency of the ion-ion plasma. [3,8,9] The generation and development of self-organized striation plasmas (SSPs) were found to be sensitive to gas pressure.…”

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confidence: 99%

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Argon self‐organized striation plasmas under kPa pressure level

Zhu

Yao

2020

Plasma Processes & Polymers

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This paper reports a study on self–organized striation plasmas generated under kPa pressure level. It focuses especially on the characteristics of argon striation plasmas, the role of metastable atoms on the generation of striation argon plasmas, and the effect of addition of gas species to the argon striation plasmas. Under our discharge conditions, the generation of argon striation plasmas is related to ionization instability, which is caused by the step‐wise ionization, deviation of the distribution from Maxwellian electron energy distribution, and inhomogeneous gas heating. Nitrogen can effectively quench the argon metastable atoms; therefore, it significantly affects the formation of striation plasma.

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Section: Ev) + Ar (1s )mentioning

confidence: 99%

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confidence: 99%

Argon self‐organized striation plasmas under kPa pressure level

Zhu

Yao

2020

Plasma Processes & Polymers

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“…Moving and standing striations were observed in both direct current (DC) and radio-frequency (RF) discharges. 7,8 There are several type of striations which can be described using either the hydrodynamic or kinetic approach. 9 At high currents, the electrons are thermalized due to electron-electron Coulomb collisions.…”

Section: Introductionmentioning

confidence: 99%

“…Then, one can use the hydrodynamic approach for striations modeling. 8 At high gas pressures, the hydrodynamic approach is justified by frequent electron-neutral collisions. At intermediate pressures, the electron kinetics is non-local and stratification can be described only using the kinetic approach.…”

Section: Introductionmentioning

confidence: 99%

Electron kinetics in standing and moving striations in argon gas

Levko

2021

Physics of Plasmas

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The electron kinetics in moving and standing striations in direct current and radio-frequency discharges is studied. The discharge current is such that the thermalizing electron-electron collisions are negligible and the hydrodynamic description of electron component of plasma is not valid. Therefore, the onedimensional hybrid model is used which models the electrons using the Particle-in-Cell/Monte Carlo collisions method. It is obtained that the electron transport is non-local in space. The electron energy distribution in both discharges is of non-equilibrium nature which is responsible for the non-linearity of the ionization frequency. However, their dynamics differs significantly. Namely, in the direct current discharge the high-energy tail is populated by the striation passage, while in the radio-frequency discharge the electron energy relaxation time is such that the electron distribution function does not react on the oscillating electric field but is defined by the effective electric field.

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“…29,30 The non-linear dependence of the ionization rate on the electron density is shown to be the main underlying mechanism of the striation phenomena. 34 1. Effect of gas pressure and RF power In this section, the effect of the gas pressure and RF power on discharge parameters are presented, such as the voltage and current amplitude (V MAX , I MAX ), the phase between voltage and current (f), the discharge impedance (Z), and the self-bias voltage (V bias ).…”

Section: A First Characterization (Reactor A)mentioning

confidence: 99%

Experimental and numerical study of the plasma in coaxial capacitive coupled radio frequency discharge

Alhomsi

Bauville

Pasquiers

et al. 2021

Journal of Applied Physics

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A coaxial configuration of discharge is proposed for plasma surface treatment and possibly other applications. The reactor is based on a cylindrical structure, with the inner cylinder radio frequency powered (RF, 13.56 MHz) and the outer cylinder grounded, playing the role of a guard ring. The charged species can escape from the inner cavity through two longitudinal slits made in both cylinders, aligned to each other, and producing a linear slab of plasma. Hence, it is possible to project the plasma directly onto a surface placed under the slits, called external plate. The operation of this device is uniform and stable in argon for a large pressure range (0.8-50 mbar). Furthermore, simulations using the Plasimo™ software package were performed to evaluate the plasma parameters and to explain the experimental results. The ion flux on the surface exposed to this plasma increases when RF power increases, and the pressure or gap distance to the plate decreases. This cylindrical capacitive coupled plasma configuration can be very effective for surface treatment of different materials (conductors or insulators) on large area (when the plate or the system is moving perpendicular to the slits) due to energetic ions and active species released from the plasma.

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Plasma stratification in radio-frequency discharges in argon gas

Cited by 31 publications

References 17 publications

Argon self‐organized striation plasmas under kPa pressure level

Argon self‐organized striation plasmas under kPa pressure level

Electron kinetics in standing and moving striations in argon gas

Experimental and numerical study of the plasma in coaxial capacitive coupled radio frequency discharge

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